Methods and systems for connecting and metering distributed energy resource devices

ABSTRACT

An electric meter socket includes: a first plurality of connection points within the electric meter socket configured to form electrical connections to line voltage wirings of an electric distribution system; a second plurality of connection points within the electric meter socket configured to form electrical connections to output voltage wirings of a DER device; one or more connection points within the electric meter socket configured to form an electrical connection of neutral wires of the electric distribution system, the DER device, and a load; and a plurality of receptacles, each of the plurality of receptacles electrically connected to a corresponding connection point and configured to accept a mating connector of an electric meter.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/244,701, filed Jan. 10, 2019, entitled “Methods And Systems ForConnecting And Metering Distributed Energy Resource Devices,” the fulldisclosure of which is hereby incorporated herein in its entirety.

BACKGROUND

Distributed Energy Resource (DER) devices, for example, solar panels,electric vehicle batteries, etc., are typically wired into the grid viaa connection into a circuit breaker in an electrical panel within acustomer's premises. If metering of the DER device is required, aseparate meter is mounted on the customer's wall for this purpose. Oneor more disconnect switches are also mounted on the customer's wall.

In some installations, a collar is added between the meter socket andthe meter. Included in this collar are circuit breakers and/ordisconnect switches, and terminal block connections to connect a DERdevice to a meter to measure the energy flow to or from the DER device.

Currently there is no standard method to connect DER devices to thegrid. Existing methods are often complicated and present an unaestheticsolution attached on the side of a wall, for example, at a customer'sresidence.

SUMMARY

Systems and methods for connecting and metering distributed energyresource devices are provided.

According to various aspects of the present disclosure there is providedan electric meter socket. In some aspects, the electric meter socket mayinclude: a first plurality of connection points within the electricmeter socket configured to form electrical connections to line voltagewiring of an electric distribution system; a second plurality ofconnection points within the electric meter socket configured to formelectrical connections to output voltage wirings of a DER device; one ormore third connection points within the electric meter socket configuredto form an electrical connection of neutral wires of the electricdistribution system, the DER device, and a load; and a plurality ofreceptacles, each of the plurality of receptacles electrically connectedto a corresponding connection point and configured to accept a matingconnector of an electric meter.

The electric meter socket may further include a third plurality ofconnection points within the electric meter socket configured to formelectrical connections to the load. The neutral wire of the load may beconnected to the one or more connection points within the electric metersocket forming an electrical connection with the neutral wires of theelectric distribution system and the DER device.

Each of the first plurality of connection points within the electricmeter socket may correspond to line voltage wirings of the electricdistribution system with voltages having different electrical phases.

The electric meter socket may further include a controllable electricaldisconnect switch configured to connect and disconnect the DER devicefrom the electric distribution system based on power production andconsumption requirements of the electric distribution system and the DERdevice. The controllable electrical disconnect switch may also beconfigured to connect and disconnect the DER device from the electricdistribution system based on a command received from the electric meter.

The electric meter socket may further include a circuit breakerconnected between the line voltage wiring of the DER device and thecorresponding receptacles. The circuit breaker may be configured todisconnect the DER device from the electric distribution system on anoccurrence of an electrical fault.

According to various aspects of the present disclosure there is providedan electric meter. In some aspects, the electric meter may include: aplurality of connectors configured to form electrical connections tocorresponding receptacles in an electric meter socket, where at leastone electrical connection to the plurality of receptacles may be formedwith a neutral wire;

and a plurality of measurement devices configured to measure electricalcharacteristics of voltage and current waveforms provided to theelectric meter from an electric distribution system and a distributedenergy resource (DER) device via the plurality of connectors.

The plurality of measurement devices may be configured to measureelectrical characteristics of voltage and current waveforms provided toa load. The neutral wire may provide an electrical reference point formeasurement of the voltage waveforms.

The plurality of measurement devices may include a plurality of voltagetransformers. Each of the plurality of voltage transformers may beconfigured to individually measure voltage characteristics of one of aplurality of line voltages provided from the electric distributionsystem or output voltage provided by the DER device. Each of theplurality of line voltages provided from the electric distributionsystem may have a different electrical phase. Measurements of thevoltage characteristics may be performed between line voltage wirings ofthe electric distribution system and the neutral wire.

The plurality of measurement devices may include a plurality of currenttransformers. The plurality of current transformers may be configured toindividually measure current consumed by a load on each line voltagewiring connected to the load and current provided by the line voltagewirings of the electric distribution system and the output voltagewirings of the DER device.

According to various aspects of the present disclosure there is provideda system for connecting and metering distributed energy resourcedevices. In some aspects, the system may include: an electric meter; andan electric meter socket configured to accommodate the electric meter.The electric meter socket of the system may include a first plurality ofconnection points within the electric meter socket configured to formelectrical connections to line voltage wiring of an electricdistribution system; a second plurality of connection points within theelectric meter socket configured to form electrical connections to linevoltage wirings of a DER device; one or more third connection pointswithin the electric meter socket configured to form an electricalconnection of neutral wires of the electric distribution system, the DERdevice, and a load; and a plurality of receptacles, each of theplurality of receptacles electrically connected to a correspondingconnection point and configured to accept a mating connector of anelectric meter.

The electric meter socket of the system may further include a thirdplurality of connection points within the electric meter socketconfigured to form electrical connections to a load. The neutral wire ofthe load may be connected to the one or more connection points withinthe electric meter socket forming an electrical connection with theneutral wires of the electric distribution system and the DER device.

Each of the first plurality of connection points within the electricmeter socket of the system may correspond to line voltage wirings of theelectric distribution system with voltages having different electricalphases.

The electric meter socket of the system may further include acontrollable electrical disconnect switch configured to connect anddisconnect the DER device from the electric distribution system based onpower production and consumption requirements of the electricdistribution system and the DER device. This controllable electricaldisconnect switch may also be a standalone device separate from theelectric meter socket. The controllable electrical disconnect switch mayalso be configured to connect and disconnect the DER device from theelectric distribution system based on a command received from theelectric meter.

The electric meter socket of the system may further include a circuitbreaker connected between the line voltage wirings of the DER device andthe corresponding receptacles. The circuit breaker may be configured todisconnect the DER device from the electric distribution system on anoccurrence of an electrical fault.

The electric meter of the system may include: a plurality of connectorsconfigured to form electrical connections to corresponding receptaclesin an electric meter socket, wherein at least one electrical connectionto the receptacles may be formed with a neutral wire; and a plurality ofmeasurement devices configured to measure electrical characteristics ofvoltage and current waveforms provided to the electric meter from theelectric distribution system and a distributed energy resource (DER)device via the plurality of connectors.

The plurality of measurement devices may include measurement devicesconfigured to measure electrical characteristics of voltage and currentwaveforms provided to a load. The neutral wires may provide anelectrical reference point for measurement of the voltage waveforms.

The plurality of measurement devices may include a plurality of voltagetransformers. Each of the plurality of voltage transformers may beconfigured to individually measure voltage characteristics of one of aplurality of line voltages provided from the electric distributionsystem or output voltage provided by the DER device. Each of a pluralityof line voltages provided from the electric distribution system may havea different electrical phase. Measurements of the voltagecharacteristics may be performed between the line voltage wirings of theelectric distribution system and the neutral wires.

The plurality of measurement devices may include a plurality of currenttransformers. The plurality of current transformers may be configured toindividually measure current consumed by the load on each of the linevoltage wirings connected to the load and current provided by the linevoltage wirings of the electric distribution system and the DER device.

Numerous benefits are achieved by way of the various embodiments overconventional techniques. For example, the various embodiments provide amore aesthetically pleasing and simpler installation as compared toconventional meter installations. In some embodiments, integratingmetering and processing into a single meter may form a basis forutilization of the meter as a home energy controller to manage allenergy aspects of a residential home or commercial building. These andother embodiments along with many of its advantages and features aredescribed in more detail in conjunction with the text below and attachedfigures.

BRIEF DESCRIPTION OF THE DRAWINGS

Aspects and features of the various embodiments will be more apparent bydescribing examples with reference to the accompanying drawings, inwhich:

FIG. 1 is a block diagram illustrating electrical connections to aconventional meter and meter socket;

FIG. 2A is a diagram illustrating the ANSI standard 14S form metersocket, the 15S form meter socket, the 16S form meter and socket, andtheir standard connections;

FIG. 2B is a diagram illustrating a modified ANSI standard 5S form metersocket with three additional lugs to add connectivity to a DER deviceaccording to various aspects of the present disclosure;

FIG. 3A is a schematic diagram of a meter and a meter socket accordingto various aspects of the present disclosure;

FIG. 3B is a schematic diagram of a meter and a meter socketillustrating another embodiment of an electric meter having a disconnectswitch and additional measurement points according to various aspects ofthe present disclosure;

FIG. 4 is a diagram of the electrical connection in a meter socketaccording to various aspects of the present disclosure;

FIG. 5A is a diagram illustrating an ANSI standard 2S meter formaccording to various aspects of the present disclosure; and

FIG. 5B is a diagram illustrating an embodiment of a third electricmeter according to various aspects of the present disclosure.

DETAILED DESCRIPTION

While certain embodiments are described, these embodiments are presentedby way of example only, and are not intended to limit the scope ofprotection. The apparatuses, methods, and systems described herein maybe embodied in a variety of other forms. Furthermore, various omissions,substitutions, and changes in the form of the example methods andsystems described herein may be made without departing from the scope ofprotection.

FIG. 1 is a block diagram 100 illustrating electrical connections to aconventional meter and meter socket. The meter and meter socket arelocated at the customer premises. The meter measures and controls theelectricity delivered to the customer premises via the electricdistribution system (i.e., the grid). The meter may be combined with acommunications module to enable the meter to communicate with othermeters and with the utility. As illustrated in FIG. 1, power from thegrid 110 (i.e., the electric distribution system) is supplied to themeter socket 120 via electrical wiring L1 and L2. Electrical wiring L1and L2 may provide power from two phases of the grid. The neutral wireN, sometimes referred to as ground, is connected between the grid 110and the electrical service 140, for example, at an electrical servicepanel at a residential or commercial customer premises. The neutral wireN does not have a connection within the conventional meter socket.

The electrical service 140 is also connected to the meter socket 120 viacorresponding electrical wiring L1 and L2. The meter socket 120 includeselectrical connectors to provide electrical connections to the meter 130when the meter 130 is plugged into the meter socket 120. An electricalconnection between the grid 110 and the electrical service 140 is formedthrough the meter 130 when the meter 130 is plugged into the metersocket 120. Within the meter 130, voltage and current provided by thegrid 110 to the electrical service 140 is measured, or metered, bymeasuring devices 135, for example, voltage transformers and currenttransformers. Power delivered to the electrical service 140 may becalculated based on the voltage and current measurements. Theconventional meter socket 120 and meter 130 do not accommodate theadditional connections required for a DER device.

Currently there is no standard method for connecting DER devices to thegrid. Existing methods are often complicated and present an unaestheticsolution attached on the side of a wall, for example at a customer'sresidence. Many electricity markets require that power produced by DERdevices be metered so that the utility can get credit for meeting anacceptable threshold of energy produced using renewable resources or forother reasons. A disconnect switch is required to disconnect theelectrical power output of the DER device from the meter or meter socketto permit a technician to work on the electrical meter or meter socket.A circuit breaker is required in-line with the DER device to protectagainst surge and other events.

In addition to delivering power, the grid may also accept powergenerated by DER devices, collectively referred to herein as distributedgeneration devices, at customer premises. Various definitions of DERdevice have been used. For the purpose of this disclosure, a DER deviceis defined as any resource on the electric distribution system (i.e.,the grid) that produces or stores electricity that can be sold back tothe distribution system, or any large load device that can be controlledin order to manage overall peak load of the distribution system. Thespecific case of a DER device that is most prevalent is a residentialsolar installation, with or without local battery storage. The devicesused to connect DER devices to the grid are separate and distinct fromthe utility meter located at the customer premises. They requireadditional installation and wiring and increase the complexity of theconnections to the grid.

Various aspects of the present disclosure provide a simple, aestheticmethod to connect a DER device to the electric distribution system viathe meter socket and meter. Some aspects may include integration of theDER metering into the meter and/or the disconnect switch and circuitbreaker into the meter socket. In accordance with various aspects of thepresent disclosure, methods of connecting a DER devices to a meterthrough a meter socket are provided.

An ANSI standard 2S form meter and meter socket are installed at most USresidences. A 2S meter form has 4 connections, L1 and L2 from the lineside (i.e., the electric distribution system), and L1 and L2 from theload side (i.e., the residential or commercial electrical service). Inaccordance with various aspects of the present disclosure, themechanical form of any of ANSI standard 14S/15S/16S form meters may berepurposed (i.e., modified) to physically connect three additionalconnections from the DER device, i.e., L1, L2, and Neutral to enableconnection of the DER device to the electric meter through the metersocket.

One of ordinary skill in the art will appreciate that while ANSIstandard 14S/15S/16S and 5S form meters and meter sockets are mentioned,these are merely exemplary and other meter and meter socket forms may beused, modified, or created to perform the intended functions withoutdeparting from the scope of the present disclosure.

FIG. 2A is a diagram illustrating the ANSI standard 14S form metersocket 200, the 15S form meter socket 210, the 16S form meter socket220, the 5S form meter socket 250, and their standard connections. Asillustrated in FIG. 2A, each of the 14S, 15S, and 16S meter formsprovide six electrical connections between the grid 230 and the load 240within the meter socket, while the 5S meter form provides eightelectrical connections between the grid 230 and the load 240 within themeter socket. In each meter form, wiring for electrical phases A, B, andC provided from the grid 230 are connected within the meter socket;however, a connection 245 of the meter to the neutral wire N is formedoutside of the meter socket.

FIG. 2B is a diagram illustrating a modified ANSI standard 5S form metersocket with three additional lugs to add connectivity to a DER deviceaccording to various aspects of the present disclosure. As illustratedin FIG. 2B, the 5S form socket 250 provides seven connections: sixelectrical connections between the grid 230 and the load 240 within themeter socket that may be used to connect L1 and L2 line voltages (i.e.,grid 310 voltages), and L1 and L2 DER output voltages, L1 and L2 loadvoltages, as well as a seventh connection from the neutral wire (N) tothe meter socket.

In accordance with various aspects of the present disclosure, theneutral wire connection may be formed within the meter socket. FIG. 3Ais a schematic diagram 300 of a meter and a meter socket according tovarious aspects of the present disclosure. Referring to FIG. 3, wiringsfrom the grid 310 (i.e., Line), the DER device 320, and the electricalservice 330 may be connected into connection points within the metersocket 340. A neutral wire N connection 342 may be formed at aconnection point within the meter socket 340 to connect the neutralwires from the grid 310, the DER device 320, and the electrical service330.

The connection points may provide electrical connections tocorresponding receptacles within the meter socket 340. For example, theconnection points for the lines L1 and L2 from the grid 310 may beelectrically connected to corresponding receptacles. The lines L1 and L2from the grid 310 may provide voltages having different electricalphases. Similarly, the lines L1 and L2 from the DER device 320 and thelines L1 and L2 to the electrical service 330 may be electricallyconnected to corresponding receptacles. The lines L1 and L2 from the DERdevice 320 may provide voltages having different electrical phases. Theconnection point for the neutral wire N may also be electricallyconnected to a corresponding receptacle.

The receptacles included in the meter socket 340 may accommodateinsertion of mating connectors, for example, but not limited to, bladeconnectors, on the first electric meter 350 to form electricalconnections between the meter socket 340 and the first electric meter350. As illustrated in FIG. 3A, when the connectors of the firstelectric meter 350 are inserted into the receptacles of the meter socket340, electrical connections may be formed between the first electricmeter 350 and the lines L1 and L2 from the grid 310, between the firstelectric meter 350 and the lines L1 and L2 from the DER device 320, andbetween the first electric meter 350 and the lines L1 and L2 to theelectrical service 330.

In addition, when the connectors of the first electric meter 350 areinserted into the receptacles of the meter socket 340, an electricalconnection may be formed between the neutral wire N in the meter socket340 and the first electric meter 350. The electrical connection of theneutral wire N into the meter socket 340 and the first electric meter350 may provide an electrical reference point to enable voltagemeasurements from L1 to neutral and L2 to neutral at the meter. Theability to perform these voltage measurements at the meter may allow formore advanced and higher fidelity metering than is possible with astandard 2S meter form, which only has L1 and L2 connections available(i.e., no neutral N connection) and therefore can only measure line toline voltage (i.e., from L1 to L2). The first electric meter 350 may beconfigured to perform current measurements on the L1 and L2 lines fromthe grid 310, the DER device 320 and the electrical service 330. Theability to perform L1 to neutral and L2 to neutral at the meter voltagemeasurements at the meter as well as the current measurements may enableimplementation of various applications, for example, but not limited to,load disaggregation algorithms.

The L1 and L2 lines from the grid 310 may provide line voltages havingdifferent electrical phases. The different electrical phases begenerated by a local distribution transformer (e.g., a pole-mountedtransformer located near the meter) or may be different electricalphases generated at a substation. Similarly, the L1 and L2 lines fromthe DER device 320 may provide line voltages having different electricalphases. The electrical phases on the line voltage provided by the DERdevice may be synchronized with the electrical phases of the linevoltages provided by the DER device. Embodiments of meter sockets andmeters in accordance with the present disclosure may include more orless connection points and/or receptacles corresponding to differentphases of line voltages. For example, when only one line voltage phaseis connected (e.g., phase A) fewer connection points and receptacles maybe included in the meter socket. Similarly, when three line voltagephases are connected (e.g., phases A, B, and C) additional connectionpoints and receptacles may be included in the meter socket.

FIG. 4 is a diagram 400 of the electrical connections in a meter socket410 in accordance with various aspects of the present disclosure.Referring to FIG. 4, the meter socket 410 may include a plurality ofreceptacles 411-417, for example, seven or another number ofreceptacles. The number of receptacles 411-417 the meter socket 410 maycorrespond to a number of mating connectors on the meter 420. Inaccordance with various aspects of the present disclosure, a metersocket 410 and meter 420 having seven or more receptacles/connectors maybe suitable for implementing load disaggregation algorithms with anappropriate number of current transformers 421 (e.g., four or anothernumber of current transformers) included in the meter 420.

As illustrated in FIG. 4, first and second receptacles 411, 412 mayprovide electrical connections to the meter 420 for line voltages L1 andL2 from the grid (e.g., the grid 310). Third and fourth receptacles 413,414, may provide electrical connections to the meter 420 for linevoltages L1 and L2 from the DER device (e.g., the DER device 320). Fifthand sixth receptacles 415, 416 may provide electrical connections to theelectrical service (e.g., the electrical service 330) for line voltagesL1 and L2 from the meter 420. The seventh receptacle 417 may provide anelectrical connection from the neutral wire in the meter socket 410 tothe meter 420. Providing a connection of the neutral wire into the meter420 may enable the measurement devices (e.g., voltage transformers,current transformers, or other measurement devices) contained in themeter 420 to perform voltage measurements at the meter on the linevoltages L1 and L2 from both the grid and the DER device in order todetermine power provided or consumed by the grid and the DER.

Referring again to FIG. 3A, the meter socket 340 may include anintegrated first controllable electrical disconnect switch 344 and/or acircuit breaker 346 that may be configured to disconnect and/or protectthe DER device. For example, a single device may perform both functionsor a circuit breaker and a separate service disconnect device todisconnect the L1 and L2 from the DER device. Alternatively, theelectrical disconnect switch and/or the circuit breaker may be locatedexternal to the meter socket 340 while leaving the mechanicalconnections through the first electric meter 350 and meter socket 340 asdescribed above.

The first controllable electrical disconnect switch 344 may include aprocessor (not shown) and a communications module (not shown). The firstcontrollable electrical disconnect switch 344 may operate automaticallyto disconnect the DER device 320 from the grid 310, for example, when ahigh load is detected or when disconnected from the meter. In someembodiments, the first controllable electrical disconnect switch 344 mayoperate automatically to disconnect the DER device 320 from the grid 310based on a command received from the first electric meter 350 or anotherdevice. The first controllable electrical disconnect switch 344 mayenable connecting the DER device 320 to the first electric meter 350 tomeasure the DER device 320 power production/consumption as a separatevalue to the energy consumed from or sent back to the electricdistribution system (i.e., the grid 310) thereby providing billabledata. The billable data (consumption from the grid or production fedback to the grid) may be metered within the electricity meter using “netmetering” or similar methods.

The first electric meter 350 may measure and control the electricitydelivered to the electrical service 330 via the grid 310 and/or the DERdevice 320. The first electric meter 350 may include a communicationsmodule (not shown) and a processor (not shown). The processor may be amicroprocessor; however, embodiments in accordance with the presentdisclosure are not limited to this implementation. For example, theprocessor may be a microprocessor, microcomputer, computer,microcontroller, programmable controller, or other programmable device.One of ordinary skill in the art will appreciate that other variationsmay be implemented without departing from the scope of the presentdisclosure.

The communications module may communicate via RF, cellular, PLC, or anyother suitable communications technology. The communications module mayreceive communications via a network that include instructions forcontrolling the controllable electrical disconnect switch. Thecommunications module may transmit information related to the operationof the meter and the measurements performed by the measurement devicesin the meter to other devices on the network or a to central system.

FIG. 3B is a schematic diagram 375 of a meter and a meter socketillustrating another embodiment of an electric meter 380 having adisconnect switch and additional measurement points according to variousaspects of the present disclosure. Referring to FIG. 3B, the grid 310,DER device 320, electrical service 330, and meter socket 340 illustratethe same components that perform the same functions as the schematicdiagram 300 of FIG. 3A and therefore will not be further described here.The second electric meter 380 may include the same components thatperform the same measurement functions as the first electric meter 350in FIG. 3A and therefore those components will not be further describedhere.

The second electric meter 380 may further include a second controllableelectrical disconnect switch 385. The second controllable electricaldisconnect switch 385 may be configured similarly to the firstcontrollable electrical disconnect switch 344 to perform similarfunctions and therefore will not be further described here. The secondcontrollable electrical disconnect switch 385 may be configured todisconnect the second electric meter 380 from the L1 and L2 connectionsto the grid 310. The ability to disconnect the second electric meter 380from the grid 310 may enable “islanding,” i.e., disconnecting from thegrid 320 and supplying power only from the DER device 320. The secondelectric meter 380 may also provide voltage measurement capability fromL1 to neutral and L2 to neutral on the grid 310 side of the secondcontrollable electrical disconnect switch 385. The ability to measure L1to neutral and L2 to neutral voltages on the grid 310 side of the secondcontrollable electrical disconnect switch 385 may enable phasesynchronization of the grid 310 voltages and the DER device voltageswhen the second electric meter 380 is reconnected to the grid 310.

While FIGS. 3A, 3B, and 4 illustrate a meter socket and meter havingseven connections, embodiments in accordance with the present disclosureare not limited to this implementation. For example, some embodimentsmay include a different number of connections, for example, more or lessthan seven connections, without departing from the scope of the presentdisclosure.

In accordance with various aspects of the present disclosure, where theDER device consists of some form of electricity generator, for example,but not limited to, solar, wind, etc., and a storage device, the metermay use information about the electric distribution system. Theinformation, may include, for example, but not limited to, real-timeelectricity pricing or other information, to make decisions and tocontrol the DER system. For example, the meter may use information todetermine whether the DER system/device should send energy to the grid(e.g., from solar or battery storage, where battery storage couldinclude batteries within an electric vehicle or similar), whether theDER system/device should consume energy from the grid (e.g., to chargestorage or allow large loads such as water heaters, pool pumps, etc., torun), and/or whether the DER system/device should disconnect from thegrid, i.e., not consume energy from the grid or send energy to the grid.Appropriate control actions may be initiated by the meter based on thedetermination. One or ordinary skill in the art will appreciate that theabove examples of decisions and control are not exhaustive and thatother decisions and control operations may be performed withoutdeparting from the scope of the present disclosure.

In accordance with various aspects of the present disclosure, methodssimilar to those described above may be employed to add DER deviceswitching and measurement capability to a meter socket having ANSI 1S,3S, 4S, 5S, and/or 12S, meter forms or other meter forms.

An ANSI standard 2S form meter socket and meter are installed at most USresidences. FIG. 5A is a diagram illustrating an ANSI standard 2S meterform according to various aspects of the present disclosure. Asillustrated in FIG. 5A, the 2S form socket 510 provides only fourreceptacles 515 a-515 d for electrical connections between the L1 and L2line voltages (i.e., grid 310 voltages) and the L1 and L2 load voltageswithin the meter socket. In accordance with various aspects of thepresent disclosure, the 2S meter form may be modified for use with amodified electric meter to provide a connection to a DER device.

Referring to FIG. 5A, the standard 2S form meter socket 510 may bemodified to include a “pigtail” wiring harness 520 (i.e., separate wiresnot connected to the receptacles in the 2S socket) for connecting L1 andL2 voltages of a DER device as well as the neutral wire (N) to theelectric meter. FIG. 5B is a diagram illustrating an embodiment of athird electric meter according to various aspects of the presentdisclosure. Referring to FIG. 5B, the third electric meter 550 mayinclude four blade connectors 555 a-55 d. The four blade connectors 555a-55 d on the third electric meter 550 may provide electricalconnections to the four receptacles for the L1 and L2 line voltages andthe L1 and L2 load voltages within the meter socket.

The third electric meter 550 may also include a terminal block 560, forexample, but not limited to, a screw-type terminal block or another typeof terminal block. The terminal block 560 may be configured to form amechanical and electrical connection to L1 and L2 voltage wires of theDER device and the neutral wire contained in the pigtail wiring harness520 of the modified 2S form meter socket 510.

In accordance with various aspects of the present disclosure, DER devicemetering may occur as a separate small form factor device external tothe electric meter, either within the meter socket or external to themeter socket.

Embodiments in accordance with the present disclosure may providenumerous advantages over conventional techniques. Installation issimpler than alternative methods, for example, a neutral connection fromthe collar to the electrical panel is not required. The neutralconnection is now one of the connections in the meter socket allowingthe neutral wire to run with the rest of the wires in the conduit to theelectrical panel. No power connections are made directly to a collar ormeter so no conduit is required on top of the meter base. Thus,homeowners/solar installers/DER device installers can swap out theirexisting meter socket for the meter socket described herein thatcontains the additional connectors to connect the DER device. A meteraccording to the various embodiments may then be connected.

Embodiments in accordance with the present disclosure are moreaesthetically pleasing than alternative installations since it has thesame look and the same number of high level components at the meter asthe non-DER solution. A second meter is not required and is not mountedon the customer's wall. Redundant components and circuitry areeliminated as compared with alternative installations. By integratingall metering and processing into a single meter, a second processor,power supply, and communications device can be eliminated, and cost tothe customer may also be reduced.

In accordance with various aspects of the present disclosure,integrating metering and processing into a single meter may form a basisfor utilization of the meter as a home energy controller to manage allenergy aspects of a residential home or commercial building. Forexample, embodiments according to the present disclosure may be suitablefor implementing load disaggregation algorithms for the electricalservice.

The examples and embodiments described herein are for illustrativepurposes only. Various modifications or changes in light thereof will beapparent to persons skilled in the art. These are to be included withinthe spirit and purview of this application, and the scope of theappended claims, which follow.

What is claimed is:
 1. An electric meter socket, comprising: a firstplurality of connection points within the electric meter socketconfigured to form electrical connections to line voltage wirings of anelectric distribution system; a second plurality of connection pointswithin the electric meter socket configured to form electricalconnections to output voltage wirings of a distributed energy resource(DER) device; one or more third connection points within the electricmeter socket configured to form an electrical connection of neutralwires of the electric distribution system, the DER device, and a load; aplurality of receptacles, each of the plurality of receptacleselectrically connected to a corresponding connection point andconfigured to accept a mating connector of an electric meter; and acontrollable electrical disconnect switch configured to connect anddisconnect the DER device from the electric distribution system based onpower production or consumption requirements of the electricdistribution system and the DER device.
 2. The electric meter socket ofclaim 1 Error! Reference source not found., wherein the controllableelectrical disconnect switch is configured to connect and disconnect theDER device from the electric distribution system based on a commandreceived from the electric meter.
 3. The electric meter socket of claim1, further comprising: a circuit breaker connected between the outputvoltage wirings of the DER device and corresponding receptacles, whereinthe circuit breaker is configured to disconnect the DER device from theelectric distribution system on an occurrence of an electrical fault. 4.A system for connecting and metering distributed energy resourcedevices, the system comprising: an electric meter; and an electric metersocket configured to accommodate the electric meter, wherein theelectric meter socket comprises: a first plurality of connection pointswithin the electric meter socket configured to form electricalconnections to line voltage wirings of an electric distribution system;a second plurality of connection points within the electric meter socketconfigured to form electrical connections to output voltage wirings of adistributed energy resource (DER) device; one or more third connectionpoints within the electric meter socket configured to form an electricalconnection of neutral wires of the electric distribution system, the DERdevice, and a load; and a plurality of receptacles, each of theplurality of receptacles electrically connected to a correspondingconnection point and configured to accept a mating connector of theelectric meter.
 5. The system of claim 4, wherein the electric metersocket comprises: a third plurality of connection points within theelectric meter socket configured to form electrical connections to aload, wherein a neutral wire of the load is connected to the one or morethird connection points within the electric meter socket forming anelectrical connection with the neutral wires of the electricdistribution system and the DER device.
 6. The system of claim 4,wherein each of the first plurality of connection points within theelectric meter socket corresponds to line voltage wirings of theelectric distribution system with voltages having different electricalphases.
 7. The system of claim 4, wherein the electric meter socketcomprises: a controllable electrical disconnect switch configured toconnect and disconnect the DER device from the electric distributionsystem based on power production or consumption requirements of theelectric distribution system and the DER device.
 8. The system of claim7 wherein the controllable electrical disconnect switch is configured toconnect and disconnect the DER device from the electric distributionsystem based on a command received from the electric meter.
 9. Thesystem of claim 4, wherein the electric meter socket comprises: acircuit breaker connected between the output voltage wirings of the DERdevice and corresponding receptacles, wherein the circuit breaker isconfigured to disconnect the DER device from the electric distributionsystem on an occurrence of an electrical fault.